Acute Kidney Injury Results in Long-Term Diastolic Dysfunction That Is Prevented by Histone Deacetylase Inhibition

Growing epidemiological data demonstrate that acute kidney injury (AKI) is associated with long-term cardiovascular morbidity and mortality. Here, the authors present a 1-year study of cardiorenal outcomes following bilateral ischemia-reperfusion injury in male mice. These data suggest that AKI causes long-term dysfunction in the cardiac metabolome, which is associated with diastolic dysfunction and hypertension. Mice treated with the histone deacetylase inhibitor, ITF2357, had preservation of cardiac function and remained normotensive throughout the study. ITF2357 did not protect against the development of kidney fibrosis after AKI

GM1 asymmetry in the membrane stabilizes pores

Cell membranes are highly asymmetric and their stability against poration is crucial for survival. We investigated the influence of membrane asymmetry on electroporation of giant unilamellar vesicles with membranes doped with GM1, a ganglioside asymmetrically enriched in the outer leaflet of neuronal cell membranes. Compared to symmetric membranes, the lifetimes of micronsized pores are about an order of magnitude longer suggesting that pores are stabilized by GM1. Internal membrane nanotubes caused by the GM1 asymmetry, obstruct and additionally slow down pore closure, effectively reducing pore edge tension and leading to leaky membranes. Our results point to the drastic effects this ganglioside can have on pore resealing in biotechnology applications based on poration as well as on membrane repair processes

Studies of human arm movements using three joints: control strategies for a manipulator with redundant degrees of freedom

Dean J, Brüwer M, Steinkühler U, Cruse H. Studies of human arm movements using three joints: control strategies for a manipulator with redundant degrees of freedom. In: Gupta M, Sinha NK, eds. Intelligent Control Systems. IEEE Press; 1993

Copper-dependent metabolism of Cu,Zn-superoxide dismutase in human K562 cells. Lack of specific transcriptional activation and accumulation of a partially inactivated enzyme.

The regulation of Cu,Zn-superoxide dismutase by copper was investigated in human K562 cells. Copper ions caused a dose- and time-dependent increase, up to 3-fold, of the steady-state level of Cu,Zu-superoxide dismutase mRNA. A comparable increase was also observed for actin and ribosomal protein L32 mRNAs, but not for metallothionein mRNA which was augmented more than 50-fold and showed a different induction pattern. The copper-induced mRNAs were actively translated as judged from their enhanced loading on polysomes, the concomitantly increased cellular protein levels and an augmented incorporation of [3H]lysine into acid-precipitable material. Cu,Zn-superoxide dismutase protein followed this general trend, as demonstrated by dose- and time-dependent increases in immunoreactive and enzymically active protein. However, a specific accumulation of Cu,Zn-superoxide dismutase was noticed in cells grown in the presence of copper, that was not detectable for other proteins. Purification of the enzyme demonstrated that Cu,Zn-superoxide dismutase was present as a reconstitutable, copper-deficient protein with high specific activity (kcat./Cu = 0.89 x 10(9) M-1.s-1) in untreated K562 cells and as a fully metallated protein with low specific activity (kcat./Cu = 0.54 x 10(9) M-1.s-1) in copper-treated cells. Pulse-chase experiments using [3H]lysine indicated that turnover rates of Cu,Zn-superoxide dismutase in K562 cells were not affected by growth in copper-enriched medium, whereas turnover of total protein was significantly enhanced as a function of metal supplementation. From these results we conclude that: (i) unlike in yeast [Carrì, Galiazzo, Ciriolo and Rotilio (1991) FEBS Lett. 278, 263-266] Cu,Zn-superoxide dismutase is not specifically regulated by copper at the transcriptional level in human K562 cells, suggesting that this type of regulation has not been conserved during the evolution of higher eukaryotes; (ii) copper ions cause an inactivation of the enzyme in intact K562 cells; and (iii) the metabolic stability of Cu,Zn-superoxide dismutase results in its relative accumulation under conditions that lead to increased protein turnover

Interferon-induced transmembrane protein 3 blocks fusion of diverse enveloped viruses by altering mechanical properties of cell membranes

Interferon-induced transmembrane protein 3 (IFITM3) potently inhibits entry of diverse enveloped viruses by trapping the viral fusion at a hemifusion stage, but the underlying mechanism remains unclear. Here, we show that recombinant IFITM3 reconstituted into lipid vesicles induces negative membrane curvature and that this effect maps to its small amphipathic helix (AH). We demonstrate that AH (i) partitions into lipid-disordered domains where IAV fusion occurs, (ii) induces negative membrane curvature, and (iii) increases lipid order and membrane stiffness. These effects on membrane properties correlate with the fusion-inhibitory activity, as targeting the ectopically expressed AH peptide to the cytoplasmic leaflet of the cell plasma membrane diminishes IAV–cell surface fusion induced by exposure to acidic pH. Our results thus imply that IFITM3 inhibits the transition from hemifusion to full fusion by imposing an unfavorable membrane curvature and increasing the order and stiffness of the cytoplasmic leaflet of endosomal membranes. Our findings reveal a universal mechanism by which cells block entry of diverse enveloped viruses

Studies of human arm movements using three joints: control strategies for a manipulator with redundant degrees of freedom

Dean J, Brüwer M, Steinkühler U, Cruse H. Studies of human arm movements using three joints: control strategies for a manipulator with redundant degrees of freedom. In: Gupta MM, Sinha NK, Institute of Electrical and Electronics Engineers, eds. Intelligent control systems: Theory and practice. New York: IEEE-Press; 1996: 820

Rational design and functional expression of a constitutively active single-chain NS4A-NS3 proteinase.

The proteinase domain of the hepatitis C virus NS3 protein is involved in the maturation of the viral polyprotein. A central hydrophobic domain of the NS4A protein is required as a cofactor for its proteolytic activity. The three-dimensional structure of the proteinase domain alone and complexed with an NS4A-derived peptide has been solved recently and revealed that the N terminus of the proteinase is in near proximity to the C terminus of the cofactor. To study the molecular basis of the enzyme activation by its cofactor and to overcome the difficulties of structural and functional investigation associated with a two-species complex, we rationally designed a link to bridge the two molecules in order to have a single polypeptide construct.The engineered construct led to the production of a stable, monomeric protein with proteolytic activity that is independent from the addition of a synthetic peptide representing the cofactor domain of the NS4A protein. The protein is active on both protein and synthetic peptide substrates. Spectroscopic and kinetic analysis of the recombinant NS4A-NS3 single-chain proteinase demonstrated features superimposable with the isolated NS3 proteinase domain complexed with the NS4A cofactor.We designed a very tight connection between the NS3 and NS4A polypeptide chains with the rationale that this would allow a more stable structure to be formed. The engineered single-chain enzyme was indistinguishable from the NS3 proteinase complexed with its NS4A cofactor in all enzymatic and physico-chemical properties investigated